Determining the current return path integrity in an electric device connected or connectable to a further device

ABSTRACT

A method for determining current return path integrity in an electric device with a plurality of signal lines and supply lines. A library with at least one reference signal pattern of a near end crosstalk signal on a defined signal line arising from an input signal on another defined signal line is provided, a predetermined signal to a selected signal line of the electric device is applied, the near end crosstalk signal on at least one further signal line of the electric device is detected, said near end crosstalk signal is compared with the corresponding reference signal pattern from the library, and if there is a deviation between the near end crosstalk signal and the corresponding reference signal pattern, an information that there is any defect in the electric device is displayed.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Ser. No. 14/796,595, entitled“DETERMINING THE CURRENT RETURN PATH INTEGRITY IN AN ELECTRIC DEVICECONNECTED OR CONNECTABLE TO A FURTHER DEVICE,” which is a continuationof U.S. Ser. No. 13/565,159, filed Aug. 2, 2012 and issued as U.S. Pat.No. 9,134,364 on Sep. 15, 2015, which is a continuation of U.S. Ser. No.12/523,119, filed Jul. 14, 2009 and issued as U.S. Pat. No. 8,248,082 onAug. 21, 2012, which is a U.S. National Phase Application ofPCT/EP2007/062542, filed on Nov. 20, 2007, and published in English onJul. 24, 2008 as WO 2008/086908 and claims priority of EP ApplicationNo. 07100678.7 filed on Jan. 17, 2007, each of which is herebyincorporated herein by reference in its entirety.

BACKGROUND

The present invention relates to a method for determining the currentreturn path integrity in an electric device with a plurality of signallines and supply lines, wherein said electric device is connected orconnectable to a further device. In particular, the invention relates toa method for determining the current return path integrity in aconnector receptacle with a plurality of signal lines and supply lines,wherein said receptacle is connected or connectable to a printed circuitboard. Further the present invention relates to a test device forperforming the above method.

An electric device with a plurality of signal lines and supply lines isusually connected to a further electric device. For example, saidelectric device may be a connector receptacle and said further electricdevice may be a printed circuit board. The connector receptacle isconnected to the printed circuit board by a plurality of solderingjoints. There are at least two types of supply lines, for example VDDlines and GND (ground) lines, where VDD stands for the positive supplyvoltage of an integrated circuit. If a circuit or device on the printedcircuit board requires several voltages, then there are a correspondingnumber of different voltage lines. For example, an integrated circuitcan require an additional negative voltage supply line VSS.

The supply lines, in particular the VDD and GND lines are provided forthe power distribution in a printed circuit board. The supply lines ofthe same type are interconnected together and are therefore redundantsupply lines. Each redundant supply line of the connector assembly isconnected to a corresponding supply trace on the printed circuit boardby a soldering joint. If there is an opening in said soldering joint,then the connection is maintained via the other supply lines of the sametype. If a direct current is applied to the supply lines, then thesingle opening has no influence to the electric properties of the supplylines.

However, if an alternating current with a high frequency is applied tothe supply lines or the signal lines, then the opening in the solderingjoint causes a substantial change of the electric properties of thewhole electric device. The supply lines, e.g. the VDD and GND lines arecoupled capacitive and inductive to the signal lines. The supply linesare utilized as high frequency signal return paths. Losing one or moreof those signal return paths causes additional impedance mismatches andan increased signal-to-signal coupling, which may be seriously impacthigh-speed system performance and reliability.

Therefore it is important to test high-speed signal paths after assemblyas accurately as possible. In selected cases this can be done on a testbench. However, there is a serious problem, if an online assemblyinspection of large connectors with more than 1000 signal connectors hasto be done.

Known electric online testing methods allow the detection of signalshorts and openings as well as inter-power shorts. In the case ofredundant VDD and GND connections it is very difficult to detect one ormore openings by an AC (Alternating Current) and/or DC (Direct Current)resistance measurements. Additionally the location of the malicioussignal return path opening has to be known to identify the affectedsignal traces.

Further an optical inspection, e.g. by X-ray, is manually possible insome cases. However, said optical inspection is very difficult and timeconsuming. The optical inspection also depends on human factors.Especially large and complex structured connector assemblies withthousands of signals require online testing methods during themanufacturing process.

There is no known method for an automatic testing to electricallylocalize redundant VDD and/or GND openings. Therefore the test coverageof high-speed links and interfaces is significantly exposed. This leadsto data integrity and functionality problems during initial system testand thereby to increased hardware cost and system test delay.

BRIEF SUMMARY

It is an object of the present invention to provide an effective methodfor determining the current return path integrity in an electric devicewith a plurality of signal lines and supply lines. It is further anobject of the present invention to provide a test device for performingsaid method.

The above object is achieved by a method as laid out in the independentclaims. Further advantageous embodiments of the present invention aredescribed in the dependent claims and are taught in the descriptionbelow.

One idea of the invention is the use of the near end crosstalk signal tolocalize a defect in a redundant supply line, e.g. a redundant VDD orGND line. An input signal is applied to a signal line and the near endcrosstalk signal on at least one neighboring signal line is detected. Ifthere is an opening in a redundant supply line in the neighborhood ofthose signal lines, then there is a deviation between the actual nearend crosstalk signal and a reference signal pattern.

The reference signal pattern has been taken from a library withreference signal patterns for a plurality of signal line pairs. Thereference signal patterns have been determined on an efficient referencedevice of the same type, which has been positively tested before byanother method.

The near cross talk signal is detected within a time windowcorresponding to the length of the tested signal lines in the electricdevice, in particular in the connector receptacle. Thus only defects inor on the connector receptacle are detected. The electric device may betested independently of the properties of the further device. Theconnector receptacle may be tested independently of the properties ofthe printed circuit board.

The deviation between the actual near end crosstalk signal and thereference signal pattern indicates that there is a defect. Theproperties of said deviation indicate the kind and the localization ofthe defect. Return path openings cause increased near end crosstalksignals on the neighboring signal lines. The nature of the time domainof the near end crosstalk signal allows the precise determination of thecoupling location.

The unplugged connector allows an access to each signal pin. The methodmay be performed automatically by a test device. The distance to thesoldering joints on the printed circuit board to be checked is in therange of some 10 mm.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The above as well as additional objectives, features and advantages ofthe present invention become apparent in the following detailed writtendescription.

The novel and inventive features believed to be the characteristics ofthe invention are set forth in the appended claims. The invention itselfand its advantages are best understood by reference to the followingdetailed description of preferred embodiments in conjunction with theaccompanied drawings, wherein:

FIG. 1 illustrates a schematic diagram of a connector receptacle on aprinted circuit board provided for a method according to a preferredembodiment of the present invention, and

FIG. 2 illustrates schematically an output signal detected by a methodaccording to a preferred embodiment of the present invention andcompared by a reference signal pattern.

DETAILED DESCRIPTION

FIG. 1 illustrates a schematic diagram of a connector receptacle 10 on aprinted circuit board 40. A method according to a preferred embodimentof the present invention may be applied to the connector receptacle 10on the printed circuit board 40.

The connector receptacle 10 includes a plurality of pins. A first pin 12and a second pin 16 as well as a redundant GND pin 14 are explicitlyshown in FIG. 1. The first pin 12 and the second pin 16 are provided tocouple the connector receptacle 10 to a cable or the like. The pins arearranged on the same side of the connector receptacle 10. Inside theconnector receptacle 10 there is a plurality of signal and supply lines.A first signal line 22, a second signal line 26 and a GND line 24 areexplicitly shown in FIG. 1. For example, the connector receptacle 10 isbuilt up by a plurality of identical wafers.

The connector receptacle 10 is connected to the printed circuit board 40via a plurality of soldering joints. A first soldering joint 32, aredundant GND soldering joint 34 and a second soldering joint 36 areexplicitly shown in FIG. 1. The soldering joints 32, 34 and 36 may beprovided as SMT (Surface-Mounting Technology) pads, for example. Thefirst signal line 22 connects the first pin 12 to the first solderingjoint 32. The second signal line 26 connects the second pin 16 to thesecond soldering joint 36. The GND signal line 24 connects the redundantGND pin 14 to the redundant GND soldering joint 34.

The printed circuit board 40 comprises a plurality of signal and supplytraces. A first signal trace 42, a redundant GND trace 44 and a secondsignal trace 46 are explicitly shown in FIG. 1. The first signal trace42, the redundant GND trace 44 and the second signal trace 46 may beprovided as conductor paths, for example. The first signal trace 42 isconnected to the first soldering joint 32. The redundant GND trace 44 isconnected to the redundant GND soldering joint 34. The second signaltrace 46 is connected to the second soldering joint 36.

The connector receptacle 10 may include a very large number of pins 12,14 and 16. There are known connector assemblies with more than 1000pins, for example. Thus the connector receptacle 10 includes also saidlarge number of signal lines 22 and 26 and supply lines 24. Further theprinted circuit board 40 comprises such a large number of solderingjoints 32, 34 and 36, signal traces 42 and 46 and supply traces 44. Theprinted circuit board 40 may be a part of a high-end server, forexample.

The method according to the present invention allows for checking of thequality of the signals transferred by the signal lines 22 and 26 in theconnector receptacle 10. In particular, said method allows identifyingany openings on the neighboring supply lines 24 within the connectorreceptacle 10 and on the soldering joint 34.

An input signal 18 is applied to the first pin 12 of the connectorreceptacle 10. The input signal 18 is provided as a voltage step, inparticular a fast voltage step. The input signal 18 propagates from thefirst pin 12 through the connector receptacle 10 via the first signalline 22 to the first soldering joint 32. The first signal line 22 iscoupled capacitive and inductively to the supply line 24 and to thesecond signal line 26. The coupling strength depends on the geometricrelations between the signal lines 22 and 26 and the supply line 24.

The coupling of the signal lines 22 and 26 and the supply line 24 resultin far end crosstalk signals and near end crosstalk signals. The far endcrosstalk signal is the superposition of all partial couplingcontributions along the signal paths. The pattern of the far endcrosstalk signal always consists of one single voltage peak. The sizeand the sign of said voltage peak depend on the inductive and capacitivecoupling balance. The near end crosstalk signal contains those partialcontributions timely separated. Thus the amount of each single partialcoupling contribution can be separated and quantified. If there is anopening in the redundant GND line 24 or in the soldering joint 34, thenthe near end crosstalk signal is changed.

Separating the redundant GND line 24 and the redundant GND trace 44 byremoving the solder joint 34 results in an opening in the redundant GNDpath. This opening causes a changed output signal 20. This output signal20 is a near end crosstalk signal, which is at least partially higherthan a corresponding reference signal pattern. For example, the outputsignal 20 increases from 1 mV to 3 mV due to the opening in the solderjoint 34.

The output signal 20 is compared with a reference signal pattern of areference output signal. The reference signal pattern has been detectedwith an efficient reference device, i.e. a connector receptacle of thesame type. The reference device has been tested before by anothermethod. The reference signal patterns of said reference device has beenstored in a library.

Each deviation between the output signal 20 and the reference outputsignal corresponds with an opening in a neighboring signal path. In onepreferred embodiment the input signal 18, the output signal 20 and thereference output signal are the corresponding voltages as a function ofthe time.

FIG. 2 illustrates schematically the output signal 20 and a referencesignal pattern 50 from a method according to a preferred embodiment ofthe present invention. The output signal 20 as well as the referencesignal pattern 50 shows the voltage as a function of the time. Forexample, the output signal 20 and the reference signal pattern 50 arerepresented by numerical values. The voltages and the correspondingtimes may be ordered as pairs in a table.

The time window has typically a width of about some 100 ps. The lengthof the signal lines 22 and 26 are known. Further the propagationvelocity of the signals 18 and 20 are also known. With this informationthe opening in the GND line 24 may be localized by the time at which thedeviation between the output signal 20 and the reference signal pattern50 occurs.

Since the time window of the output signal 20 is limited to apredetermined range of time, which corresponds with the length of thesignal lines 22 and 26, the connector receptacle 10 may be testedindependent of the electric properties of the printed circuit board 40or any further electric device coupled to said connector receptacle 10.Within this time window only such deviations may be detected, whichoccur from an opening in a supply line 26 in the neighborhood of thesignal lines 22 and 26.

Due to the direct relationship between time and frequency domain allsaid analysis of signal 20 and comparison to reference signal 50 canalso be applied in the frequency domain. The relationship between timeand frequency domain is illustrated by Fourier transformation, forexample.

A controllable test device is provided for performing the methodaccording to the present invention. The test device allows an automaticexecution of the above method. The test device comprises a test head,which may be connected to the connector receptacle 10. The test headsequentially moves along all pins 12, 14 and 16 of the connectorreceptacle 10. The test device initiates one or more voltage steps 18 oneach pin 12, 14 and 16 and records the resulting near end crosstalksignals of the next neighboring lines.

Such a test device has a resolution of about 100 μV. If the deviationbetween the output signal 20 and the reference output signal is greaterthan a predetermined value, then the test device displays that the testwas not successful. If the deviation between the output signal 20 andthe reference output signal is smaller than said predetermined value,then the test device displays that the test was successful. For example,these results may be displayed by a red and green LED, respectively.

A simple prototype implementation of the test device uses a TektronixCSA 8000 communication signal analyzer device. The CSA 8000 allows usinga TDR (Time Domain Reflectometry) test head. This TDR test head iscontrolled by a robot arm device. A PC (Personal Computer) controls theCSA 8000 and the robot arm. The library of reference signal patterns ismaintained by a computer program executed on the PC, which is performinga method in accordance with the present invention. The computer programdisplays the test results on a computer monitor connected to the PC.

In manufacturing lines specially designed industry robots could be usedinstead. In order to reduce the test time, the testing can beparallelized by using multiple test heads. For example, industry robotscan have multiple robot arms in order to control multiple test heads atonce.

A modification of the inventive method would be this method with anextended time window in order to detect openings on the printed circuitboard 40 or on another electric device coupled to the connectorreceptacle 10.

Further, the inventive method may be provided for performing asimulation of the behavior of the electric crosstalk signal.

The inventive method can be combined with other testing methods. Inparticular, the inventive method may be combined with a de-embeddingmethod. This allows the test of assemblies with long wires. Ade-embedding method is described in the “TDR Primer”, application notepublished in Printed Circuit Design Magazine, April 2002. Thisapplication note contains several further references to publications onde-embedding methods.

The method according to the present invention may be used to test cableconnections. Further the inventive method may be used to test theconductor paths and/or the other connections on printed circuit boards.

Moreover the inventive method may be used to test arbitrary solderingjoints. Especially soldering joint in the range of some μm can betested.

In general, the inventive method can be used to test the quality ofsignals in arbitrary electric devices with several lines.

The present invention can also be embedded in a computer programproduct, which comprises all the features enabling the implementation ofthe methods described herein. Further, when loaded in a computer system,said computer program product is able to carry out these methods.

Although illustrative embodiments of the present invention have beendescribed herein with reference to the accompanying drawings, it is tobe understood that the present invention is not limited to those preciseembodiments, and that various other changes and modifications may beaffected therein by one skilled in the art without departing from thescope or spirit of the invention. All such changes and modifications areintended to be included within the scope of the invention as defined bythe appended claims.

List of Reference Numerals

-   10 connector receptacle-   12 first pin-   14 redundant GND pin-   16 second pin-   18 input signal-   20 output signal, near end crosstalk signal-   22 first signal line-   24 redundant GND line-   26 second signal line-   32 first soldering joint-   34 redundant GND soldering joint-   36 second soldering joint-   40 printed circuit board-   42 first signal trace-   44 redundant GND trace-   46 second signal trace-   50 reference signal pattern

What is claimed is:
 1. A method for determining a current return pathintegrity in an electric device, the method comprising: applying asignal to a selected signal line of a plurality of signal lines of theelectric device; detecting a crosstalk signal on at least one othersignal line of the plurality of signal lines of the electric device;comparing the detected crosstalk signal with a reference signal pattern;and identifying whether a deviation between the detected crosstalksignal and the reference signal pattern exists.
 2. The method of claim1, wherein the signal is provided as a voltage step.
 3. The method ofclaim 1, wherein the crosstalk signal is a near end crosstalk signal. 4.The method of claim 1, wherein the identifying identifies that adeviation between the detected crosstalk signal and the reference signalpattern exists, indicating that there is at least one open in theelectric device, and wherein the method further comprises, based onidentifying that the deviation exists, providing an indication thatthere is at least one open in the electric device.
 5. The method ofclaim 4, wherein providing the indication that there is at least oneopen is based further on the identified deviation between the crosstalksignal and the corresponding reference signal pattern being greater thana predetermined value.
 6. The method of claim 1, wherein the selectedsignal line is a signal line of a group of signal lines of the pluralityof signal lines of the electric device, the group of signal lineselectrically interconnected together to form an interconnected group ofsupply lines.
 7. The method of claim 6, wherein the identifyingidentifies that a deviation between the detected crosstalk signal andthe reference signal pattern exists, indicating that there is at leastone open in the electric device, and wherein the method furthercomprises, based on identifying that the deviation exists, providing anindication that there is at least one open in the interconnected groupof supply lines.
 8. The method of claim 1, wherein the method furthercomprises obtaining the reference signal pattern from a library ofreference signal patterns.
 9. The method of claim 1, wherein the methodfurther comprises repeating, for each additional signal line of one ormore additional signal lines of the plurality of signal lines, theapplying, the detecting, the comparing, and the identifying.
 10. Themethod of claim 1, wherein the detecting comprises detecting thecrosstalk signal within a time window that is adapted to a length of theselected signal line and a propagation velocity of the signal applied tothe selected signal line.
 11. The method of claim 1, wherein the openingis localized on the basis of the time at which the deviation between thecrosstalk signal and the corresponding reference signal pattern occurs.12. A computer program product for determining a current return pathintegrity in an electric device, the computer program productcomprising: a storage medium readable by a computer and storinginstructions for execution by the computer for performing a methodcomprising: applying a signal to a selected signal line of a pluralityof signal lines of the electric device; detecting a crosstalk signal onat least one other signal line of the plurality of signal lines of theelectric device; comparing the detected crosstalk signal with areference signal pattern; and identifying whether a deviation betweenthe detected crosstalk signal and the reference signal pattern exists.13. The computer program product of claim 12, wherein the signal isprovided as a voltage step.
 14. The computer program product of claim12, wherein the crosstalk signal is a near end crosstalk signal.
 15. Thecomputer program product of claim 12, wherein the selected signal lineis a signal line of a group of signal lines of the plurality of signallines of the electric device, the group of signal lines electricallyinterconnected together to form an interconnected group of supply lines.16. The computer program product of claim 15, wherein the identifyingidentifies that a deviation between the detected crosstalk signal andthe reference signal pattern exists, indicating that there is at leastone open in the electric device, and wherein the method furthercomprises, based on identifying that the deviation exists, providing anindication that there is at least one open in the interconnected groupof supply lines.
 17. A test device comprising: a test head connected orconnectable to an electric device, the test device to perform a methodcomprising: applying a signal to a selected signal line of a pluralityof signal lines of the electric device; detecting a crosstalk signal onat least one other signal line of the plurality of signal lines of theelectric device; comparing the detected crosstalk signal with areference signal pattern; and identifying whether a deviation betweenthe detected crosstalk signal and the reference signal pattern exists.18. The test device of claim 17, wherein the signal is provided as avoltage step.
 19. The test device of claim 17, wherein the crosstalksignal is a near end crosstalk signal.
 20. The test device of claim 17,wherein the selected signal line is a signal line of a group of signallines of the plurality of signal lines of the electric device, the groupof signal lines electrically interconnected together to form aninterconnected group of supply lines, and wherein the identifyingidentifies that a deviation between the detected crosstalk signal andthe reference signal pattern exists, indicating that there is at leastone open in the electric device, and wherein the method furthercomprises, based on identifying that the deviation exists, providing anindication that there is at least one open in the interconnected groupof supply lines.